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Enhanced Entity-Relationship and UML Modeling

Chapter 4. Enhanced Entity-Relationship and UML Modeling. Enhanced-ER (EER) Model Concepts. EER Model : Includes all modeling concepts of basic ER and Additional concepts : Subclasses/ superclasses .( lớp con/ lớp cha) Specialization( chuyên biệt )/generalization( tổng quát ).

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Enhanced Entity-Relationship and UML Modeling

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  1. Chapter 4 Enhanced Entity-Relationship and UML Modeling

  2. Enhanced-ER (EER) Model Concepts • EER Model: Includes all modeling concepts of basic ER and Additional concepts: • Subclasses/superclasses.(lớpcon/lớp cha) • Specialization(chuyênbiệt)/generalization(tổngquát). • Categories, attribute inheritance (phâncấp) • It is used to model applications more completely and accurately if needed • It includes some object-oriented concepts, such as inheritance

  3. Subclasses and Superclasses • An entity type may have additional meaningful subgroupings of its entities • Example: Employee may be further grouped into Secretary, Engineer, Manager, Technician,… Each of these groupings is a subset of EMPLOYEE entities • Each is called a subclass of EMPLOYEE • EMPLOYEE is the superclass for each of these subclasses • These are called superclass/subclass relationships. • Example: • Employee/secretary. • Employee/technician

  4. Employees Subclasses and Superclasses Engineer Technician Secretary Manager SuperClass SubClasses

  5. Subclasses and Superclasses • Inheritance attribute: • Subclass will inherit some attributes and relationships of the Superclass and itsseft attributes. • Relationship between Superclasses and Subclasses is ISA

  6. Subclasses and Superclasses

  7. Specialization • Specialization (chuyênbiệt): Is the process of defining a set of subclasses of a superclass • The set of subclasses is based upon some distinguishing characteristics of the entities in the superclass • Example: • {SECRETARY, ENGINEER, TECHNICIAN} is a specialization of EMPLOYEE based upon job type. • May have several specializations of the same superclass

  8. Specialization • Example: Another specialization of EMPLOYEE based in method of pay is {SALARIED_EMPLOYEE, HOURLY_EMPLOYEE}. • Superclass/subclass relationships and specialization can be diagrammatically represented in EER diagrams • Attributes of a subclass are called specific attributes. For example, TypingSpeed of SECRETARY • The subclass can participate in specific relationship types. For example, BELONGS_TO of HOURLY_EMPLOYEE

  9. Example of a Specialization

  10. Generalization (tổngquáthóa) • The reverse of the specialization process • Several classes with common features are generalized into a superclass; original classes become its subclasses • Example: CAR, TRUCK generalized into VEHICLE; both CAR, TRUCK become subclasses of the superclass VEHICLE. • We can view {CAR, TRUCK} as a specialization of VEHICLE • Alternatively, we can view VEHICLE as a generalization of CAR and TRUCK

  11. Generalization (tổngquáthóa)

  12. Constraints on Specialization/Generalization • Two other conditions apply to a specialization/generalization • DisjointnessConstraint: • Specifies that the subclasses of the specialization must be disjointed (an entity can be a member of at most one of the subclasses of the specialization). Specified by d in EER diagram • Overlapingcontraint: that is the same entity may be a member of more than one subclass of the specialization. Specified by o in EER diagram

  13. Constraints on Specialization/Generalization

  14. Constraints on Specialization/Generalization

  15. Constraints on Specialization/Generalization • Completeness Constraint: • Total (Ràngbuộctoànbộ): specifies that every entity in the superclass must be a member of some subclass in the specialization/ generalization. • Shown in EER diagrams by a double line • Partial(Ràngbuộctừngphần): allows an entity not to belong to any of the subclasses • Shown in EER diagrams by a single line.

  16. Constraints on Specialization/Generalization

  17. Constraints on Specialization/Generalization • Hence, we have four types of specialization/generalization: • Disjoint, total • Disjoint, partial • Overlapping, total • Overlapping, partial • Note: Generalization usually is total because the superclass is derived from the subclasses.

  18. Example of disjoint partial Specialization

  19. Specialization Hierarchies and Lattices(chuyênbiệtphâncấp and lưới) • A subclass may itself have further subclasses specified on it • Forms a hierarchy or a lattice • Hierarchy has a constraint that every subclass has only one superclass (called single inheritance) • In a lattice, a subclass can be subclass of more than one superclass (called multiple inheritance) • In a lattice or hierarchy, a subclass inherits attributes not only of its direct superclass, but also of all its predecessor superclasses

  20. Specialization Hierarchies and Lattices(chuyênbiệtphâncấp and lưới) • Specialization Lattices example:

  21. Specialization Hierarchies and Lattices(chuyênbiệtphâncấp and lưới)

  22. Specialization Shared Subclasses • Shared subclass: A subclass with more than one superclass. • Can have specialization hierarchies or lattices, or generalization hierarchies or lattices. • In specialization, start with an entity type and then define subclasses of the entity type by successive specialization (top down conceptual refinement process) • In generalization, start with many entity types and generalize those that have common properties (bottom up conceptual synthesis process)

  23. Specialization / Generalization Lattice Example (UNIVERSITY)

  24. Categories (UNION TYPES) • Superclass/subclass relationship with more than one superclass, where the superclasses represent different entity types. In this case, the subclass will represent a collection of objects that is a subset of the UNION of distinct entity types. Such a subclass is called a category or UNION TYPE. • Example: Database for vehicle registration, vehicle owner can be a person, a bank (holding a lien on a vehicle) or a company.

  25. Categories (UNION TYPES) • Category (subclass) OWNER is a subset of the union of the three superclasses COMPANY, BANK, and PERSON • A category member must exist in at least one of its superclasses • Note: The difference from shared subclass, which is subset of the intersection of its superclasses (shared subclass member must exist in all of its superclasses).

  26. Formal Definitions of EER Model (1) • Class C: A set of entities; could be entity type, subclass, superclass, category. • Subclass S: A class whose entities must always be subset of the entities in another class, called the superclass C of the superclass/subclass (or IS-A) relationship S/C: S ⊆ C • Specialization Z: Z = {S1, S2,…, Sn} a set of subclasses with same superclass G; hence, G/Si a superclass relationship for i = 1, …., n.

  27. Formal Definitions of EER Model (1) • G is called a generalization of the subclasses {S1, S2,…, Sn} • Z is total if we always have: S1 ∪ S2 ∪ … ∪ Sn = G; Otherwise, Z is partial. • Z is disjoint if we always have: Si ∩ S2 empty-set for i ≠ j; Otherwise, Z is overlapping.

  28. Formal Definitions of EER Model (2) • Subclass S of C is predicate defined if predicate p on attributes of C is used to specify membership in S; that is, S = C[p], where C[p] is the set of entities in C that satisfy p • A subclass not defined by a predicate is called user-defined • Attribute-defined specialization: if a predicate A = ci (where A is an attribute of G and ci is a constant value from the domain of A) is used to specify membership in each subclass Si in Z. • Note: If ci ≠ cj for i ≠ j, and A is single-valued, then the attribute-defined specialization will be disjoint.

  29. Formal Definitions of EER Model (2) • Category or UNION type T • A class that is a subset of the union of n defining superclass. • D1, D2,…Dn, n>1: T ⊆ (D1 ∪ D2 ∪ … ∪ Dn) • A predicate pi on the attributes of T. • If a predicate pi on the attributes of Di can specify entities of Di that are members of T. • If a predicate is specified on every Di: T = (D1[p1] ∪ D2[p2] ∪…∪ Dn[pn] • Note: The definition of relationship type should have 'entity type' replaced with 'class'.

  30. Cardinality Constraints • Cardinality Constraint: Quantification of the relationship between two concepts or classes (a constraint on aggregation) • MINIMUM (A,B) = n: At a minimum, one instance of A is related to at least n instances of B. n = 0 MIN(A,B) = 0 MIN(Person, Car) = 0 n = 1 MIN(A,B) = 1 MIN(Cust, Ship-address) = 1 n = inf. MIN(A,B) = inf. NOT POSSIBLE n = x (fixed) MIN(A,B) = x MIN(Car, Wheels) = 4

  31. Formal Definitions of EER Model (2) • MAXIMUM (A,B) = n: At a maximum, one instance of A is related to at least n instances of B n = 0 MAX(A,B) = 0 DOES NOT ARISE n = 1 MAX(A,B) = 1 MAX(Cust, Ship-address) = 1 n = inf. MAX(A,B) = inf. MAX(Cust, Orders) = inf. n = x (fixed) MAX(A,B) = x MAX(Stud, Course) = 6

  32. Participation constraints MIN (A,B) = 0 Optional Participation MIN (A,B) = 1 Mandatory Participation MAX (A,B) = 0 No Participation MIN (A,B) = x, MAX (A,B) = y Range Constrained Participation

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